WO2020020578A1

WO2020020578A1 - Turbomachine

Info

Publication number: WO2020020578A1
Application number: PCT/EP2019/067550
Authority: WO
Inventors: Alin Stirban; Martin Dreizler; Guido Daimer; Ioan Liviu Iepure; Juliane TRAUTMANN; Felix FOERSTER; Michael Mayer
Original assignee: Robert Bosch Gmbh
Priority date: 2018-07-27
Filing date: 2019-07-01
Publication date: 2020-01-30
Also published as: CN112513470A; JP2021532300A; JP7162122B2; DE102018212570A1; CN112513470B; EP3830423B1; EP3830423A1

Abstract

Turbomachine (100) having a turbo housing (56) and an impeller (1) which is mounted such that it can be moved about a rotational axis (30), which impeller (1) defines an inflow region (8) and an outflow region (9) of a working medium on a front side (20). The impeller (1) is operatively connected to a shaft (12). Furthermore, together with the turbo housing (56), the impeller (1) or the shaft (12) configures an axial bearing (27) which is embodied as a gas bearing, wherein the impeller (1) or the shaft (12) is prestressed in the direction of the axial bearing (27) by way of a prestressing means (7).

Description

description

title

turbomachinery

The present invention relates to a turbomachine which can be used, for example, in a waste heat recovery system for waste heat recovery from an internal combustion engine or as a compressor for a fuel cell system.

State of the art

From the published patent application DE 10 2014 226 951 A1, a turbo machine for an exhaust heat recovery system of an internal combustion engine is described as an example. The turbomachine has a housing in which an impeller arranged on a drive shaft is arranged. Furthermore, the turbo machine has an inflow area and an outflow area, a working medium flowing through the turbomachine during operation.

The working medium flows into the inflow area of the turbomachine along a front side of the impeller in the direction of the outflow area. There is a pressure differential between the inflow area and the outflow area. Furthermore, a pressure divider is arranged in the turbomachine near a rear of the impeller. In this way, the pressure on the rear of the impeller can be reduced in comparison to the pressure on the inflow region, in order to adjust a resulting hydraulic force acting on the impeller.

For such turbomachines, two-sided gas bearings, for example air bearings, are typically used for the bearing of the impeller. However, bilateral bearings increase thermal friction losses on the impeller, which affects the efficiency of the turbomachine. The present invention has for its object to provide a turbomachine with such a bearing, so that reliable operation and improved efficiency of the turbomachine can be achieved with simplified assembly of the rotor in the turbomachine.

Disclosure of the invention

The turbomachine according to the invention with the characterizing features of claim 1 has the advantage that friction losses are minimized and the efficiency of the turbomachine is increased by using a one-sided bearing for the impeller.

For this purpose, the turbomachine according to the invention has a turbo housing and an impeller movably mounted about an axis of rotation, which defines an inflow region and an outflow region of a working medium on a front side. Furthermore, the impeller is operatively connected to a shaft. The impeller or the shaft with the turbo housing forms a thrust bearing designed as a gas bearing, the impeller or the shaft being biased by a biasing means in the direction of the thrust bearing.

As a result, the resulting hydraulic force acts on the impeller in the direction of the axial bearing, as a result of which the impeller or the shaft is only mechanically loaded on one side, so that the impeller or the shaft is more mechanically resilient and thus an increased service life is achieved. Furthermore, the functionality of the turbomachine and its efficiency are improved.

In a first advantageous development of the invention, it is provided that the biasing means comprises a first magnet and a second magnet, preferably a permanent magnet or an electromagnet. The first magnet is advantageously arranged in the shaft and interacts magnetically with the second magnet arranged in the turbo housing. As a result, the magnets are advantageously arranged with respect to one another in such a way that they repel one another and thus preload the impeller or the shaft in the direction of the axial bearing. In a further embodiment of the invention, it is advantageously provided that the prestressing means comprises a pressure divider which is designed as a shoulder of the turbo housing and which shoulder forms a sealing gap with a rear side of the impeller. The axial force on the impeller can be reduced by reducing the pressure on the back of the impeller due to the step in the inflow area compared to the front of the impeller. In this way, wear on the impeller can be reduced and the functionality of the turbomachine can be optimized.

In an advantageous development of the invention, the pretensioning means comprises a pressure divider which is designed as at least one sliding element and is arranged between a rear side of the impeller and the turbo housing. The at least one sliding element is advantageously acted upon by a spring in the direction of the axial gap. The axial force on the impeller can be reduced by reducing the pressure on the back of the impeller compared to the front of the impeller in the inflow area, which leads to a reduction in wear and an increase

Life of the impeller.

In a further embodiment of the invention it is provided that in

Outflow area forms a hub of the shaft with a shoulder of the turbo housing an axial gap and thus forms the axial bearing for the impeller. High mechanical forces can be applied to the hub of the shaft, so that a one-sided axial bearing is formed without wear on the shaft and an improved functioning of the turbomachine is achieved.

In an advantageous development of the invention, it is provided that a

Back of the impeller with the turbo housing forms an axial gap and thus the thrust bearing. In this way, the impeller can be supported in the turbomachine and the turbomachine can function effectively.

In a further embodiment of the invention, it is provided that the axial bearing is designed as a one-sided gas bearing, for example an air bearing, for the impeller. This allows the impeller to be securely stored in the turbomachine and the turbomachine to function efficiently.

In an advantageous further development, the shaft or the impeller and the turbo housing delimit a leakage space which is connected to the axial gap. The leakage space ensures that the gas bearing is optimally formed in the axial gap, which improves the functioning of the impeller.

In advantageous uses, the turbomachine is in one

Fuel cell system arranged. The turbo machine is as

Turbo compressor or the impeller designed as a compressor. The

Fuel cell system has a fuel cell, an air supply line for supplying a working medium in the form of an oxidizing agent into the fuel cell and an exhaust gas line for removing the oxidizing agent from the fuel cell. The compressor is arranged in the air supply line. The air supply line serves the inflow of

Working fluids or oxidizing agent in the fuel cell, and the exhaust pipe serves to remove the oxidizing agent or the reacted oxidizing agent or a mixture thereof from the fuel cell. The turbo compressor is designed according to one of the embodiments described above.

The described designs of the turbomachine are preferably used in a waste heat recovery system. The

Waste heat recovery system has a circuit carrying a working medium, which comprises a fluid pump, an evaporator, a turbomachine unit and a condenser in the direction of flow of the working medium. The turbomachine unit further comprises a generator and the

turbomachine according to the invention. The efficiency of the waste heat recovery system can be increased by using the turbomachine according to the invention.

drawings

Only the main areas are shown below.

Fig.l shows schematically a known waste heat recovery system. 2 shows a section of a turbomachine unit of the waste heat recovery system from FIG. 1 in a perspective view.

3 shows a first exemplary embodiment of a turbomachine according to the invention of the turbomachine unit in area A from FIGS. F1 & 2 in longitudinal section.

4 shows a second exemplary embodiment of a turbomachine according to the invention of the turbomachine unit in area A from FIGS. F1 & 2 in longitudinal section.

5 shows a third exemplary embodiment of a turbomachine according to the invention of the turbomachine unit in area A from FIGS. F1 & 2 in longitudinal section.

6 schematically shows a known fuel cell system.

Description of the embodiments

Fig.l schematically shows a known waste heat recovery system 44 of an internal combustion engine 40, only the essential areas being shown.

The waste heat recovery system 44 has a working medium leading the circuit 32, which comprises a fluid pump 33, an evaporator 34, a turbomachine 100 and a condenser 35 in the flow direction of the working medium. The condenser 35 can be coupled to a cooling system of an internal combustion engine 40, for example.

A bypass line 36 is connected in parallel to the turbo machine 100. By means of a bypass valve 37, the mass flow of the working medium can be divided as required between the turbomachine 100 and / or the bypass line 36.

The turbomachine 100 here is part of a turbomachine unit 1000. The turbomachine unit 1000 additionally comprises a generator 42, optionally also the bypass valve 37 and the bypass line 36. The generator 42 converts the mechanical energy generated in the turbomachine 100 into electrical see energy and thus feeds not shown consumers or a storage medium.

Optionally, the waste heat recovery system 44 - as shown in FIG. 1 - can furthermore have a tank 41, from which working medium can be introduced into the circuit 32 by means of a metering valve, or can be returned to the excess working medium from the circuit 32. Alternatively, the tank 41 can also be arranged in the circuit 32.

How the waste heat recovery system works

The liquid working medium is conveyed by the fluid pump 33 under pressure to the evaporator 34 and further to the turbomachine 100. The evaporator 34 is connected to an exhaust pipe of the internal combustion engine 40, so uses the thermal energy of the exhaust gas of the internal combustion engine 40 and thus evaporates the working medium of the circuit 32. The gaseous working medium is then tensioned in the turbomachine 100 with the release of mechanical energy. The working medium is completely liquefied in the condenser 35 and thus reaches the fluid pump 33 again.

The turbomachine 100 and the generator 42 preferably have a common shaft 12, so that electrical energy can be generated in the generator 42 in a simple manner by means of a rotor 61 and a stator 59 arranged on the shaft 12 (see FIG. 2).

The bypass line 36 is arranged parallel to the turbomachine 100. Depending on the operating states of the internal combustion engine 40 and the waste heat recovery system 44 and the resulting sizes, for example temperatures of the working medium, the working medium of the turbomachine 100 is supplied or passed through the bypass line 34 to the turbomachine 100.

FIG. 2 shows a section of the turbomachine unit 1000 from FIG. 1 in a perspective view, only the essential areas being shown. The turbomachine unit 1000 includes the turbomachine 100 and the Generator 42. Turbomachine 100 is designed as a radial turbine, the flow output here leading away from generator 42 from the radial turbine.

The turbomachine unit 1000 has a housing 55. In the embodiment of F1 & 2, the housing 55 is made of several parts and comprises a turbo housing 56, a generator housing 57 and a stator plate 58. The turbo housing

56 essentially surrounds the turbomachine 100. The generator housing 57 surrounds the stator 59. The stator plate 58 is clamped between the turbo housing 56 and the generator housing 57 and, together with the generator housing 57, fixes the stator 59 within the housing 55.

A bearing 60 for supporting the shaft 12 is radial through the generator housing

57 positioned and axially positioned between the generator housing 57 and the stator plate 58, that is to say arranged between the turbomachine 100 and the generator 42. Another bearing 600 is arranged on the other side of the generator 42.

The generator housing 57 is designed in two parts, with an inner body 570 and an outer jacket 571.

The flow path of the working medium in the embodiment in FIG. 2 is as follows: Coming from the evaporator 34, the gaseous working medium flows radially into the turbomachine 100 through an inflow region 8 and axially out of it again through an outflow region 9, in the illustration in FIG .2 to the right. As a result, an impeller 1 is driven in the turbomachine 100. The working medium is then completely liquefied in the condenser 35 after it has left the turbomachine 100.

In advantageous embodiments, the impeller 1 of FIG. 2 is arranged reversed, so that the outflow takes place in the direction of the generator 42. The flow of the working medium from the turbomachine unit 1000 then preferably takes place in the radial direction between the turbo housing 56 and the generator housing 57. The outflow region 9 can for this purpose be limited by the turbo housing 56 and / or the generator housing 57. The bearing 60 is in these Versions advantageously arranged on the right edge of the turbomachine unit 1000.

In advantageous developments, the turbomachine unit 1000 then has an insulation between the turbomachine 100 and the generator 42. This can be done for example by a material of the housing 55 with low thermal conductivity, or by an additional coating of the housing 55 or by another component of the housing 55. The insulation can also include air pockets within the housing 55. The insulation has the task of thermally separating the relatively hot working medium flowing out through the outflow region 9 from the turbo machine 100 from the generator 42, so that the efficiency of the generator 42 is not reduced.

FIG. 3 shows an enlarged view A of the turbomachine 100 from FIG. 2. It shows a first embodiment of the turbomachine 100 according to the invention in longitudinal section. The turbomachine 100 has the turbo housing 56.

The impeller 1 is arranged in the turbo housing 56 so as to be rotatable about an axis of rotation 30 and is firmly connected here to the shaft 12, the shaft 12 passing through the turbo housing 56. The illustration is shown in simplified form and limited to the longitudinal section above the axis of rotation 30 and can be mirrored about the axis of rotation 30 to complete the longitudinal section.

The impeller 1 has a front 20 and a back 21. The

Front 20 is arc-shaped and thus defines the inflow area 8 and the outflow area 9 for the working medium, in the representation of F1 & 3 from above and to the right. The rear 21 has a step 29 which merges into a flat section 19. The side of the turbo housing 56 facing the rear side 21 of the impeller 1 is of stepped design. A step 22 of the turbo housing 56 forms a sealing gap 63 together with the flat section 19 of the impeller 1.

The rear 21 of the impeller 1 and the turbo housing 56 delimit a leakage space 23, which is divided by the sealing gap 63. The leakage space 23 has a hydraulic connection to the condenser 35. The impeller 1 has a hub 11 on the outflow region 9, which forms an axial gap 5 and thus an axial bearing 27 with a shoulder 10 of the turbo housing 56. The hub 11 of the impeller 1 and the turbo housing 56 delimit a further leakage space 14 which is connected to the outflow region 9 by means of a channel 2 formed in the turbo housing 56 and by means of the axial gap 5. The channel 2 is interrupted by the outflow area 9 and leads out of the turbomachine 100 on the side opposite the further leakage space 14. The axial bearing 27 is preferably designed as a closed bearing disc on the hub 11 of the impeller 1, as a result of which high load capacities can be achieved. Furthermore, various types of air bearings can be formed, for example spiral grooves, foil bearings, wedge bearings or externally pressurized bearings, so-called EP C. external pressurized bearings. An EP warehouse is built here.

The flow path of the working medium is the following: Coming from the evaporator 34, the gaseous working medium flows into the inflow region 8 of the turbomachine 100. At an edge 18 of the turbo housing 2 in

Inflow area 8 between the impeller 1 and the turbo housing 2 divides the gaseous working medium into two flow paths: one

Flow path leads past the front 20 and the other flow path past the rear 21 of the impeller 1.

At the rear 21, the gaseous working medium flows into the leakage space 23 and arrives at high pressure in the direction of the sealing gap 63. The working medium is expanded through the sealing gap 63 and then flows further in the direction of the condenser 35.

At the front 20, the gaseous working medium flows in an arc along the impeller 1 in the direction of the outflow region 9 and thereby drives the impeller 1 or the shaft 12. The gaseous working medium is thus depressurized. The gaseous working medium is then passed from the turbomachine 100 in the direction of the condenser 35 and is completely liquefied there. A portion of the gaseous working medium flows into the axial gap 5 in the direction of the further leakage space 14, and this too is hydraulically connected to the condenser 35. Pressure is applied externally through the channel 2, for example by introducing a gas into the further leakage space 14 so that the pressure in the axial gap 5 drops. The external supply of a gas via channel 2 is only necessary in an EP warehouse in order to obtain a supporting air film. For other types of storage, the external supply via channel 2 can be used for cooling.

The axial bearing 27 for the impeller 1 is formed in the axial gap 5 by means of the channel 2 and the further leakage space 14. The axial bearing 27 is designed here as a gas bearing, for example an air bearing, and forms a one-sided gas bearing for the impeller 1. Depending on the geometric design of the

Paragraph 22 of the turbo housing 56, the resulting force can be applied to the impeller 1 in the direction of the axial gap 5.

In this embodiment there is a pretensioning means 7, here as a step 22

trained pressure divider, available, which biases the impeller 1 or the shaft 12 with a force in the direction of the axial bearing 27 (see arrow P in Fig. 3).

Alternatively, a first magnet 4, for example a permanent magnet or an electromagnet, can also be arranged in the shaft 12 as a preloading means 7, which is connected to a second magnet 400, for example a

Permanent magnet or an electromagnet, magnetically interacts in the turbo housing 56. These can be arranged in relation to one another in such a way that they repel one another and thus impeller 1 or shaft 12 in

Direction of the axial bearing 27 is biased. A resulting force on the impeller 1 or the shaft 12 in the direction of the axial bearing 27 can thus be ensured. When using electromagnets 4, 400, the force on the impeller 1 or the shaft 12 can be variably adjusted.

In an alternative embodiment, one of the magnets 4, 400, designed as a permanent magnet, can also be arranged to be movable in order to vary the resulting force on the impeller 1 or the shaft 12.

FIG. 4 also shows an enlarged view A of the turbomachine 100 from FIGS. F1 & 2. It shows a second embodiment of the invention Turbo machine 100 in longitudinal section, the longitudinal section being shown only above the axis of rotation 30 for simplification and mirroring around the axis of rotation 30 to complete the longitudinal section. The second

The embodiment corresponds largely in structure and mode of operation to the first embodiment from FIG. 3.

In contrast to the first exemplary embodiment, a sliding element 13 is arranged on the rear side 21 of the impeller 1 instead of the shoulder 22 of the turbo housing 56 and the sealing gap 63. The sliding element 13 is designed here as a sealing ring made of graphite and is supported between the turbo housing 56 and the rear 21 of the impeller 1. A further sliding element 15, for example a sealing ring, is arranged in a recess 26 of the turbo housing 56, the second sliding element 15 being supported on the first sliding element 13.

Furthermore, a spring 17 is arranged in the recess 26, which presses the first sliding element 13 with a force in the direction of the rear side 21 of the impeller 1. A recess 31 is formed on the rear side 21 of the impeller 1 and is at least partially covered by the first sliding element 13. Here, the first sliding element 13, the second sliding element 15 and the spring 17 are designed as biasing means 7, which biases the impeller 1 or the shaft 12 with a force in the direction of the axial bearing 27 (see arrow P in FIG. 4).

Alternatively, as stated in the first exemplary embodiment, a first magnet 4 can interact as a biasing means 7 with a second magnet 400, for example designed as permanent magnets or electromagnets, so that the impeller 1 or the shaft 12 in the direction of the

Axial bearing 27 is biased.

The flow path of the working medium is basically the same as in the first exemplary embodiment, except for the flow path on the rear 21 of the impeller 1. Here the gaseous working medium flows around the first sliding element 13, the second sliding element 15 and the spring 17, in order then to leave the turbomachine 100 in the direction of the condenser 35. Also in this In the exemplary embodiment, the gaseous working medium is depressurized by the sliding elements 13, 15.

In an alternative embodiment, the first and second

Embodiment when using magnets 4, 400 also a

double-sided gas bearing can be used for impeller 1. The gas bearings can be loaded differently depending on the magnetic force.

5 also shows an enlarged view A of the turbomachine 100 from FIGS. F1 & 2. It shows a third embodiment of the invention

Turbo machine 100 in longitudinal section, the longitudinal section being shown only above the axis of rotation 30 for simplification and can be mirrored about the axis of rotation 30 to complete the longitudinal section.

The impeller 1 is arranged in the turbo housing 56 so as to be rotatable about the axis of rotation 30 and here is formed in one piece with the shaft 12, the shaft 12 passing through the turbo housing 56. Furthermore, as in the previous exemplary embodiments, the impeller 1 has a front side 20 and a rear side 21. The front side 20 is arcuate and thus defines the inflow area 8 and the outflow area 9 for the

Working medium, in the representation of Figure 3 from above and to the left. The back 21 is flat and designed with a step 28. Furthermore, the rear 21 of the impeller 1 and the turbo housing 56 form an axial gap 5, which forms an axial bearing 27 for the impeller 1.

Furthermore, the rear 21 of the impeller 1 and the turbo housing 56 delimit a leakage space 14 which is separated by a shoulder 24 into a first

Leakage part space 140 and a second leakage part space 141 is divided. The second leakage part space 141 is in the turbo housing 56

formed channel 16 connected, via which leakage collected in the leakage space 14 can be directed from the turbomachine 100 in the direction of the condenser 35. The shoulder 10 is formed here as a peripheral ridge on the housing part 2 and forms a sealing gap 25 with the rear 21 of the impeller 1. The flow path of the working medium is as follows: coming from the evaporator 34, the gaseous working medium flows into the inflow region 8 of the turbomachine 100. At the edge 18 of the turbo housing 2 in the inflow region 8 between the impeller 1 and the turbo housing 2, the gaseous working medium divides into two flow paths on, one flow path leads past the front 20 and the other flow path past the rear 21 of the impeller 1.

On the front side 20, the gaseous working medium flows in an arc along the impeller 1 in the direction of the outflow region 9 and is expanded by driving the impeller 1 or the shaft 12. Then the gaseous working medium from the turbomachine 100 in the direction of

Condenser 35 passed and completely liquefied there.

At the rear 21, the gaseous working medium flows into the first

Leakage sub-space 140 enters and reaches paragraph 24 with high pressure. The working medium is pressure-released through the sealing gap 25 and flows into the second leakage sub-space 141. There it flows on the one hand into the axial gap 5 between the impeller 1 and the turbo housing 56, so that the axial bearing 27 is designed as a gas bearing. On the other hand, the working medium flows out of the turbomachine 100 in the direction of the capacitor 35 via the duct 16. If the axial bearing 27 is designed as an EP bearing, an additional duct 62 would be formed in the turbo housing 56.

In this embodiment, the biasing means 7 is a first magnet 4 and a second magnet 400, for example as a permanent magnet or

Running electromagnets. The first magnet 4 is arranged in the shaft 12 and the second magnet 400 is arranged in the turbo housing 56 and have a magnetic interaction with one another. The two magnets 4, 400 can be arranged with respect to one another in such a way that they repel one another and so the impeller 1 or the shaft 12 is preloaded in the direction of the axial bearing 27 (see arrow P in FIG. 5). A resulting force on the impeller 1 or the shaft 12 in the direction of the axial bearing 27 can thus be ensured. When using electromagnets 4, 400, the force on the impeller 1 or the shaft 12 can be variably adjusted. In an alternative embodiment, one of the magnets 4, 400,

designed as permanent magnets, can be arranged to move the

to vary the resulting force on the impeller 1 or the shaft 12.

The turbomachine 100 according to the invention can, as shown in FIG. 6, also be designed as a compressor 51 in a fuel cell system 46.

6 shows a fuel cell system 46 known from DE 10 2012 224 052 A1. The fuel cell system 46 comprises a fuel cell 47, an air supply line 48, an exhaust gas line 49, the turbomachine 100 designed as a compressor 51, an exhaust gas turbine 52, and a bypass valve 50 Pressure reduction and a supply line for fuel to the fuel cell 47, not shown in detail. The bypass valve 50 can be a control flap, for example. For example, a wastegate valve can be used as the bypass valve 50.

The fuel cell 47 is a galvanic cell, the chemical reaction energy egg nes via the fuel supply line not shown fuel and an oxidizing agent converts into electrical energy, which is in the embodiment shown here, intake air that is supplied via the air supply line 48 to the fuel cell 47. The fuel may preferably be hydrogen or methane or methanol. Accordingly, water vapor or water vapor and carbon dioxide are generated as exhaust gas. The fuel cell 47 is, for example, set up to drive a Antriebsvor direction of a motor vehicle. For example, the electrical energy generated by the fuel cell 47 drives an electric motor of the motor vehicle.

The compressor 51 is arranged in the air supply line 48. The exhaust gas turbine 52 is arranged in the exhaust line 49. The compressor 51 and the exhaust gas turbine 52 are mechanically connected via a shaft 12. The shaft 12 is electrically driven by a Antriebsvorrich device 54. The exhaust gas turbine 52 is used to support the drive device 54 for driving the shaft 12 or the compressor 51. The compressor ter 51, the shaft 12 and the exhaust gas turbine 52 together form a turbo compressor 1000. In an alternative embodiment, the exhaust gas turbine 52 can also be dispensed with in the fuel cell system 46 and the compressor 51 is designed for this in several stages.

Claims

Expectations

1. Turbo machine (100) with a turbo housing (56) and one

Rotation axis (30) of a movably mounted impeller (1), which has an inflow region (8) and an outflow region (9) on a front side (20)

Working medium defines and which impeller (1) is operatively connected to a shaft (12), characterized in that the impeller (1) or the shaft (12) with the turbo housing (56) forms an axial bearing (27) designed as a gas bearing, whereby the impeller (1) or the shaft (12) is pretensioned in the direction of the axial bearing (27) by a pretensioning means (7).

2. Turbo machine (100) according to claim 1, characterized in that the biasing means (7) a first magnet (4) and a second magnet (400), preferably a permanent magnet or one

Electromagnets.

3. Turbo machine (100) according to claim 2, characterized in that the first magnet (4) is arranged in the shaft (12) and with which in the

Turbo housing (56) arranged second magnet (400) magnetically interacts.

4. turbomachine (100) according to claim 2 or 3, characterized in that the magnets (4, 400) are arranged so that they repel each other and so the impeller (1) or the shaft (12) in the direction of Thrust bearing (27) preload.

5. Turbo machine (100) according to any one of the preceding claims, characterized in that the biasing means comprises a pressure divider which is designed as a shoulder (22, 24) of the turbo housing (56) and which shoulder (22, 24) with a rear side ( 21) of the impeller (1) forms a sealing gap (9, 25).

6. Turbo machine (100) according to any one of claims 1 to 4, characterized in that the biasing means comprises a pressure divider which is designed as at least one sliding element (13) and between a rear side (21) of the impeller (1) and the turbo housing ( 56) is arranged.

7. Turbo machine (100) according to claim 6, characterized in that the at least one sliding element (13) is acted upon by a spring (17) with a force in the direction of the axial gap (27).

8. Turbo machine (100) according to any one of the preceding claims, characterized in that in the outflow region (9) a hub (11) of the shaft (12) with a shoulder (10) of the turbo housing (56) forms an axial gap (5) and so the axial bearing (27) for the impeller (1).

9. turbomachine (100) according to any one of claims 1 to 5, characterized

characterized in that a rear (21) of the impeller (1) with the

Turbo housing (56) forms an axial gap (5) and thus the axial bearing (27).

10. Turbo machine (100) according to one of the preceding claims, characterized in that the axial bearing (27) is designed as a one-sided gas bearing, for example air bearing, for the impeller (1).

11. Turbo machine (100) according to any one of the preceding claims, characterized in that the shaft (12) or the impeller (1) and that

Turbo housing (56) delimit a leakage space (14) which is connected to the axial gap (5).

12. Fuel cell system (46) with a fuel cell (47), one

Air supply line (48) for supplying a working medium in the form of an oxidizing agent to the fuel cell (47) and an exhaust gas line (49) for discharging the oxidizing agent from the fuel cell (47), characterized in that the fuel cell system (46) is used as a compressor (51) trained turbomachine (100) according to one of the preceding claims in the air supply line (48) and an exhaust gas turbine (52) are arranged in the exhaust line (49) and the Turbo machine (100) and the exhaust gas turbine (52) one

Form turbo machine unit (1000).

13. waste heat recovery system (44) with a working medium

leading circuit (32), the circuit (32) in the flow direction of the

Working medium comprises a fluid pump (33), an evaporator (34), a turbomachine unit (1000) and a condenser (35), the turbomachine unit (1000) comprising a generator (42), characterized in that the turbomachine unit (1000) has a

Turbo machine (100) according to one of claims 1 to 11.